Scientific Centre for Aerospace Research of the Earth of the Institute of Geological Sciences of the National Academy of Sciences of UkraineE: A 30-year-Old Road

1Lyalko, VI, 1Popov, MО, 1Sedlerova, OV, 1Khyzhniak, AV
1State institution «Scientific Centre for Aerospace Research of the Earth of the Institute of Geological Sciences of the National Academy of Sciences of Ukraine», Kyiv, Ukraine
Space Sci. & Technol. 2022, 28 ;(3):07-07
https://doi.org/10.15407/knit2022.03.029
Язык публикации: Ukrainian
Аннотация: 
The paper was prepared in connection with the 30th anniversary of the State Institution "Scientific Centre for Aerospace Research of the Earth IGS NAS of Ukraine". The article briefly describes the history of the development of aerospace exploration of the Earth in Ukraine and the role of the Centre in remote sensing research provided by institutions of the National Academy of Sciences of Ukraine. The history of the Centre, its scientific academic schools, and main areas of research are presented, and the prospects for further development are outlined.
     We describe the current organizational structure of the Scientific Centre for Aerospace Research of the Earth and the achievements of the scientific team. The analysis of the contribution of its employees to the development of aerospace research in Ukraine and international activities of the Centre are presented. Further prospects and plans for the development of scientific research at the Centre, which cover the basic principles of the development of world society determined by the UN decisions on sustainable development, are considered.
Ключевые слова: aerospace research, development strategy, remote sensing of the Earth, Scientific Centre, sustainable development
References: 
1. Burshtinska Kh. V., Stankevich S. A. (2010). Aerocosmic surveying systems. Text book. Lviv: Lviv Polytechnic, 246 p. [in Ukrainian].
2. DSTU 4220: 2003. Remote sensing of the Earth from space. Terms and definitions of concepts. Kyiv: State Standard of Ukraine [in Ukrainian].
3. DSTU 4758: 2007. Remote sensing of the Earth from space. Data processing. Terms and definitions of concepts. Kyiv: State Standard of Ukraine [in Ukrainian].
4. Dovgy S. O., Lyalko V. I. (Eds). (2001). Informatization of aerospace agriculture. Kyiv: Naukova Dumka, 606 p. [in Ukrainian].
5. Dovgyi S. O., Lialko V. I., Babiichuk S. M., Kuchma T. L., Tomchenko O. V., Iurkiv L. Ya. (2019). Fundamentals of remote sensing: History and practice: Guidance Manual. translation from Ukrainian Savychenko O., Oleshko O. K.: Institute of Gifted Child of the NAPS of Ukraine. 316 p. ISBN 978-617-7734-05-4
6. Lyalko V. I., Fedorovsky O. D. (Eds) (1999). Ukraine from space (Atlas of decoded pictures of the territory of Ukraine from space vehicles). 2ed. Kyiv: Naukova Dumka, 34 p. [in Ukrainian].
7. Lyalko V. I., Fedorovsky O. D. (Eds). (2001). Cosmos — Ukraine (Atlas of decoded pictures of the territory of Ukraine with spacecraft “Ocean” and other space vehicles). Kyiv: Naukova Dumka, 106 p. [in Ukrainian].
8. Lyalko V. I., Popov M. A. (Eds). (2004). Reference book with remote sensing of the Earth. Kyiv: SMP AVERS, 170 p. [in Ukrainian].
9. Lyalko V. I., Popov M. O. (Eds) (2006). Multispectral methods for remote sensing of the Earth in the problems of nature management. Kyiv: Naukova Dumka, 358 p. [in Ukrainian].
10. Lyalko V. I. (Ed.). (2010). Changes in terrestrial systems in Eastern Europe. Kyiv: Foliant publishing house, 581 p. [in Russian].
11. Lyalko V. I., Popov M. A. (Eds) (2012). Satellite methods of searching for minerals. Kyiv: Carbon-Ltd, 436 p. [in Russian].
12. Lyalko V. I. (Ed.) (2015). Greenhouse effect and climate change in Ukraine: assessments and consequences. Kyiv: Naukova Dumka, 283 p. [in Ukrainian].
13. Lyalko V. I., Popov M. O. (Eds). (2017). Modern methods of remote search for minerals. ISBN 978_966_02_8295_7 (electronic publication). Kyiv, 220 p. [in Ukrainian].
14. Michak A. G., Filipovich V. E., Prikhodko V. L., et al. (2010). Aerocosmic studies of the geological environment. Sci. method. allowance. Kyiv: Ministry of Environmental Protection of Ukraine, State Geological Survey of Ukraine, 246 p. (in Ukrainian).
15. Popov M. A., Kudashev E. B. (Eds). (2013). Infrastructure of satellite geoinformation resources and their integration: Sat. sci. words. Kyiv: Carbon-Service, 192 p. [in Russian].
16. Apostolov A. A., Yelistratova L. A., Romanciuc I. F., Zakharchuk I. (2021). Identifying potential landslide areas by employing the erosion relief index and meteorological criteria in Ukraine. Rev. Roum. Géogr. /Rom. J. Geogr., 65 (2), 125—141.
17. Apostolov O. A., Elistratova L. O., Romanchuk I. F., Chekhniy V. M. (2020). Assessment of desertification areas in Ukraine by estimation of water indexes using remote sensing data. Ukrainian Geograph. J., 1(109), 16—25.
18. Arkhipov A. I., Glazunov N. M., Khyzhniak À. V. (2018). Heuristic criterion for class recognition by spectral brightness. Cybern Syst Anal., 54, 94—98. https://doi.org/10.1007/s10559-018-0010-7
19. Artiushenko M. V., Khyzhniak A. V. (2020). Methodology of fire safety monitoring for peatlands using space survey. J. Automat. and Inform. Sci., 52, No. 7, 63—73. https://doi.org/10.1615/JAUTOMATINFSCIEN.V52.I7.60
20. Azimov O. T., Trofymchuk O. M., Kuraeva I. V., Zlobina K. S., Karmazinenko S. P., Dorofey Ye. M. (2020). Ecological and geochemical study of the state of soil deposits in the impact areas of municipal solid waste landfills. 19th EAGE Intern.
Conf. on Geoinformatics — Theoretical and Applied Aspects (11—14 May 2020, Kyiv, Ukraine): Conf. Proc., 2020, 1—7. https://doi.org/10.3997/2214-4609.2020geo133.
21. Fedorovsky O. D., Khyzhniak A. V., Tomchenko O. V. (2021). Assessing aquatic environment quality of the urban water bodies by system analysis methods based on integrating remote sensing data. Space Science and Technology, 27, No. 5, 10—18. https://doi.org/10.15407/knit2021.05.011.
22. Filipovich V., Mychak A., Krylova A. (2014). Use satellite data in monitoring ecological condition of urban landscape. 14th International Multidisciplinary Scientific GeoConference SGEM. Albena, Bulgaria, Informatics, Geoinformatics and Remote Sensing, Section Cartography and GIS. Conference Proceedings, vol. III, 1061—1068. https://doi.org/10.5593/SGEM2014/B23/S11.134
23. Filipovych V. Ye., Shevchuk R. M., Mychak A. H. (2022). Satellite imagery application for searching buried intrusive structures. Sci. innov., 18(2), 59—65. https://doi.org/10.15407/scine18.02. 59
24. Filipovych V. Ye., Lyalko V. I., Lischenko L. P., Pazynych N. V., Teremenko A. N., Krylova A. B. (2015). Remote sensing monitoring of historical centre of Kyiv for reducing risks from disasters at world heritages properties. J. Japanese Geotechnical Society Special Publication, 2(78), 2671—2675. http://doi.org/10.3208/jgssp.TC301-04
25. Golubov S. I., Vorobiev A. I., Sedlerova O. V., Yefimenko T. A. (2021). Geological interpretation of remote sensing data for deep faults identifying in the Dnieper-Donets basin. Publisher: European Association of Geoscientists & Engineers. Source: Conference Proceedings, Geoinformatics, 2021, 1—6.
26. Groisman P., Lyalko V. I. (Eds.). (2012). Earth Systems Change over Eastern Europe. Kyiv: Akademperiodyka, 488 p.
27. Kozlova A. A., Khyzhniak A. V., Piestova I. A., Andreiev A. A. (2018). Synergetic use of Sentinel-1 and Sentinel-2 data for analysis of urban development and green spaces. European Association of Geoscientists & Engineers. 17th International Conference on Geoinformatics - Theoretical and Applied Aspects, May 2018. Conference Proceedings, 2018, 1—6. DOI: https://doi.org/10.3997/2214-4609.201801846
28. Popov M. O., Stankevich S. A., Mosov S. P., Titarenko O. V., Topolnytskyi M. V., Dugin S. S. (2021). Landmine detection with UAV-based optical data fusion, IEEE EUROCON 2021 - 19th International Conference on Smart Technologies. 175—178. https://doi.org/10.1109/EUROCON52738.2021.9535553.
29. Popov M., Fedorovsky O. D., Stankevich S., Filipovich V. E., Khyzhniak A. V., Piestova I., Lubskyi M. S., Svideniuk M. (2017). Remote sensing technologies and geospatial modelling hierarchy for smart city support. ISPRS Annals of the Photogrammetry, Remote Sensing and Spatial Information Sciences, 51—56. https://doi.org/10.5194/isprs-annals-IV-5-W1-51-2017
30. Stankevich S., Piestova I., Shklyar S., Lysenko A. (2020). Satellite dual-polarization radar imagery superresolution under physical constraints. Advances in intelligent systems and computing IV. Eds N. Shakhovska, M. O. Medykovskyy. CSIT 2019. Adv. in Intelligent Systems and Computing, 1080. https://doi.org/10.1007/978-3-030-33695-0_30